Depolarizer, telescope and remote sensing device and method

The invention claimed is: 1. An optical depolarizer for depolarizing a beam having a direction of propagation along a first direction relative to the depolarizer, the beam entering through a front surface of the optical depolarizer and leaving through a back surface of the optical depolarizer, the optical depolarizer comprising: a first and second body of transparent material, adjoining the front and back surface respectively, the first and second body each having a thickness in the first direction that varies as a function of a position for entry of the beam at the front surface, a sum of the thicknesses of the first and second body being substantially independent of said position; the transparent material in the first and second body having speeds of light of first and second polarization components that are mutually different, the speed of light of the first polarization component in the first body equaling the speed of light of the second polarization component in the second body and vice versa; the front surface having a first and second planar surface part extending on first and second, mutually opposite sides from a virtual plane through the depolarizer respectively, the virtual plane being parallel to the first direction, the first and second planar surface part forming a concave angle in the front surface, the back surface having a third and fourth surface part substantially parallel to the first and second surface parts, on the first and second side of the virtual plane respectively. 2. An optical depolarizer according to claim 1 , wherein the first and second planar surface part are inclined at a same angle towards the virtual plane. 3. An optical depolarizer according to claim 2 , wherein the first and second body have further surfaces internally in the optical depolarizer, the further surfaces being flat planar surfaces both perpendicular to said virtual plane. 4. An optical depolarizer according to claim 3 , wherein the further surfaces are in contact with each other. 5. An optical depolarizer according to claim 1 , wherein the thickness of the first second body varies mirror symmetrically on mutually opposite sides of the virtual plane. 6. An optical depolarizer according to claim 1 , wherein the transparent material is a birefringent material. 7. An optical depolarizer according to claim 1 , comprising a black layer or at least a blackened layer at said virtual plane. 8. An optical depolarizer according to claim 1 , wherein the first and second planar surface part form said concave angle in the front surface along an intersection line of the first and second surface part with the virtual plane. 9. An optical depolarizer system, comprising a first and second optical depolarizer, both according to claim 1 , in series along a beam path, wherein the virtual planes of the first and second optical depolarizer are oriented in parallel to different linear polarization directions of the beam. 10. A telescope comprising: an optical depolarizer for depolarizing a beam of the telescope, the beam having a direction of propagation along a first direction relative to the depolarizer, the optical depolarizer being located substantially in a pupil plane of the telescope, the beam entering through a front surface of the optical depolarizer and leaving through a back surface of the optical depolarizer, the optical depolarizer comprising: a first and second body of transparent material, adjoining the front and back surface respectively, the first and second body each having a thickness in the first direction that varies as a function of a position for entry of the beam at the front surface, a sum of the thicknesses of the first and second body being substantially independent of said position; the transparent material in the first and second body having speeds of light of first and second polarization components that are mutually different, the speed of light of the first polarization component in the first body equaling the speed of light of the second polarization component in the second body and vice versa; the front surface having a first and second planar surface part extending on first and second, mutually opposite sides from a virtual plane through the depolarizer respectively, the virtual plane being parallel to the first direction, the first and second planar surface part forming a concave angle in the front surface, the back surface having a third and fourth surface part substantially parallel to the first and second planar surface parts, on the first and second side of the virtual plane respectively. 11. A telescope according to claim 10 , wherein the optical depolarizer or depolarizer system is positioned relative to an objective lens of the telescope so that the virtual plane divides the beam from the objective lens in parts with equal intensity. 12. A remote sensing device comprising the telescope of claim 10 and a detector having an aperture in an image plane of the telescope. 13. A method of depolarizing a light beam, using an optical depolarizer, the method comprising: applying the light beam to a front surface of an optical depolarizer, distributed over mutually opposite sides of a virtual plane parallel to a main direction of beam propagation, the front surface having a first and second planar surface part extending on first and second, mutually opposite sides from the virtual plane, the first and second planar surface part forming a concave opening angle in the front surface; providing a first body adjoining the front surface, the first body transmitting first and second polarization components of the beam with mutually different speeds of light, through a thickness of the first body that varies as a function of a position on the front surface where the beam enters; providing a second body following the first body, the second body transmitting the first and second polarization components of the beam at the speed of light of the second and first polarization component in the first body respectively, through a thickness of the first body that varies as a function of said position, the second body adjoining a back surface of the optical depolarizer, a sum of the thicknesses of the first and second body being substantially independent of said position. 14. A remote sensing method, comprising collecting light from an object into a light beam, depolarizing the light beam using the method of claim 13 , using the beam to form an image of the object onto an image plane, and sensing a property of light imaged onto a measuring position in the image plane. 15. A telescope comprising a first and second optical depolarizer for depolarizing a beam of the telescope, the beam having a direction of propagation along a first direction relative to the first and second depolarizer, the first and second optical depolarizer being located in series along a beam path substantially in a pupil plane of the telescope, the beam entering through a front surface of the first optical depolarizer and entering a front surface of the second optical depolarizer from a back surface of the first optical depolarizer, and leaving through a back surface of the second optical depolarizer, the first and second optical depolarizer each comprising: a first and second body of transparent material, adjoining the front and back surface respectively, the first and second body each having a thickness in the first direction that varies as a function of a position for entry of the beam at the front surface, a sum of the thicknesses of the first and second body being substantially independent of said position; the transparent material in the first and second